Feedback Scheme for Non-Isolated Power Supply

ABSTRACT

Embodiments described herein describe a switching power converter that includes a switch, an inductor, a diode, and a controller that generates a control signal to turn on and turn off the switch. The controller generates the control signal by generating a reference signal, integrating a difference between a voltage value of the generated reference signal, and a voltage difference between voltage values of the switching node and the second output terminal, and generating the control signal by processing the integrated voltage difference.

BACKGROUND

1. Field of the Disclosure

This disclosure generally relates to power supplies, and specifically to a feedback scheme for non-isolated power supplies.

2. Description of the Related Art

Switching power supplies are categorized into either isolated power supplies or non-isolated power supplies. In isolated power supplies, a transformer is placed between the input and output that provides galvanic isolation between the input and output. Non-isolated power supplies include a single inductor and do not have a galvanic isolation between the input and output. In a non-isolated power supply that operates on high voltages, a high voltage isolation device is typically needed to send the information about the output voltage to control the power switch. For example, a high voltage diode can be used to handle voltages as high as (or higher than to account for switching overshoots) 155V.

A conventional feedback scheme in a high voltage buck converter uses a high voltage diode (e.g., D_(FB) in FIG. 6) or a high voltage bipolar junction transistor (e.g., T2 in FIG. 7)) to send the information about the high output voltage back to a controller that generates a control signal for controlling the power switch. One disadvantage of the conventional approach is the necessity of a high voltage diode (e.g., FIG. 6) or a high voltage BJT (e.g., FIG. 7) that is expensive. Another disadvantage is a limitation on the ability to sense the output voltage only once per switching cycle and only after the switching in that cycle that increases recovery from, for example, a standby mode.

SUMMARY

Embodiments of the present disclosure herein describe a feedback scheme for non-isolated switching power converters. The switching power converter is configured to provide power to an output load, such as an LED load. The switching power converter can provide power to the output load via a single inductor for buck-boost or buck converters.

An exemplary switching power converter includes a switch, an inductor, a diode, and a controller that generates a control signal to turn on and turn off the switch. The controller generates the control signal by generating a reference signal, integrating a difference between a voltage value of the generated reference signal, and a voltage difference between voltage values of the switching node and the second output terminal, and generating the control signal by processing the integrated voltage difference.

In one embodiment, the controller generates the control signal such that an average voltage value of the output voltage over one or more of the plurality of switching cycles is the same as the voltage value of the reference signal.

In one embodiment, the controller comprises an operational amplifier implemented as an integrator, the operational amplifier integrating a voltage difference between voltages on its inverting input and non-inverting input.

In one embodiment, the controller further comprises a feedback resistor coupled between the inverting input of the operational amplifier and the second output terminal.

In one embodiment, the controller further comprises a current reference coupled between the inverting input of the operational amplifier and the switching node.

In one embodiment, the controller generates the control signal such that an average voltage difference between voltage values of the switching node and the second output terminal is same as a product of a resistance value of the feedback resistor and a current value of the current source.

In one embodiment, the controller further comprises a reference resistor and a voltage reference, the reference resistor coupled between the inverting input of the operational amplifier and the voltage reference, and the voltage reference coupled between the reference resistor and the switching node.

In one embodiment, the controller generates the control signal such that an average voltage difference between voltage values of the switching node and the second output terminal is same as a product of a ratio of resistance values of the feedback resistor and the reference resistors, and a voltage value of the voltage source.

In one embodiment, the controller is further configured to vary a time constant of the integrator without affecting an average voltage value of the output voltage, the time constant varied by changing the resistance value of the feedback resistor and the reference resistor, while keeping a ratio of resistance values of the feedback resistor and the reference resistor constant.

In one embodiment, the operational amplifier of the controller is configured such that the non-inverting input of the operational amplifier is coupled to the switching node for providing a voltage level associated with the switching node as a reference ground voltage of the operational amplifier.

Embodiments also relate to a method of controlling a switching power converter, the switching power converter including a switch coupled between an input terminal for receiving an input voltage and an switching node, an inductor coupled between the switching node and a first output terminal, and a diode coupled between the switching node and a second output terminal, the first and second output terminals configured to provide an output voltage to a load. The method comprises generating a reference signal, integrating a difference between a voltage value of the generated reference signal, and a voltage difference between voltage values of the switching node and the second output terminal, and generating a control signal by processing the integrated voltage difference, the control signal turns on and turns off the switch at each switching cycle of a plurality of switching cycles.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of a buck converter, according to an example embodiment of the present disclosure.

FIG. 2 is a timing diagram illustrating an operation of the buck converter of FIG. 1, according to an example embodiment.

FIG. 3 is a circuit diagram illustrating a feedback scheme for non-isolated power supplies using a current reference, according to an example embodiment.

FIG. 4 is a circuit diagram illustrating a feedback scheme for non-isolated power supplies using a voltage reference, according to an example embodiment.

FIG. 5 is a circuit diagram illustrating a feedback scheme for non-isolated power supplies using current mirrors, according to an example embodiment.

FIG. 6 is a circuit diagram illustrating a conventional feedback scheme for non-isolated power supplies using high voltage diode.

FIG. 7 is a circuit diagram illustrating a conventional feedback scheme for non-isolated power supplies using high voltage bipolar junction transistor.

DETAILED DESCRIPTION

The Figures (FIGS.) and the following description relate to various embodiments by way of illustration only. It should be noted that from the following discussion, alternative embodiments of the structures and methods disclosed herein will be readily recognized as viable alternatives that may be employed without departing from the principles discussed herein. Reference will now be made in detail to several embodiments, examples of which are illustrated in the accompanying figures. It is noted that wherever practicable similar or like reference numbers may be used in the figures and may indicate similar or like functionality.

This disclosure describes a feedback scheme for non-isolated power supplies that do not need a high voltage component in the feedback path even when the power supply is operating on high voltages. The feedback scheme is applicable to both buck converters and buck-boost converters. The feedback scheme senses information about the output voltage by processing a voltage across the diode of the buck converter or the buck-boost converter instead of processing the output voltage directly. The scheme takes advantage of an observation that an average value of the voltage across the diode is the same as the output voltage over one or more switching cycles.

The feedback scheme also includes generating a reference signal such that a voltage value of the reference signal is equal to the average voltage across the diode in buck converters and in buck-boost converters. Any difference between the voltage of the generated reference signal and that of the voltage across the diode is integrated and the integrated voltage difference is pulse width modulated to generate a control signal to control on and off time of the switch. By processing the voltage across the diode instead of the output voltage, the information about the output voltage can be obtained continuously. And by referring to a switching node of the buck converter or the buck-boost converter as a negative supply voltage of the controller, the need for active high voltage components in the feedback path is eliminated.

FIG. 1 illustrates a buck converter according to an example embodiment of the present disclosure. Although the converter 100 of FIG. 1 is a buck converter, it should be noted that present disclosure is not limited to a buck converter and that it can be applied to other converters such as a buck-boost converter. The buck converter 100 includes, among other components, a switch S, an inductor L, a diode D, and a capacitor C. The buck converter 100 receives an input voltage from a DC power supply VIN and outputs an output voltage to a load resistor R_(L). Throughout the present disclosure the terms “converter” and “power supply” are recited to convey the same meaning and can be used interchangeably.

A buck converter is a non-isolated type of switched-mode power supply that does not include a transformer. The buck converter is voltage step down converter that converts an input voltage to an output voltage, where a voltage value of the output voltage is lower than a voltage value of the input voltage. For example, a 310 V input voltage is converted to a 12V output voltage. The buck converter 100 receives an input DC voltage VIN and outputs a DC output voltage across the load resistor R_(L). The input DC voltage source VIN is coupled between INP node and OUT2 node, and the load resistor R_(L) is coupled between OUT1 and OUT2 nodes. The switch S is coupled between INP node and SW node, which can also be referred to as a switching node. The inductor L is coupled between switching node SW and first output node OUT1. The diode is coupled between the switching node SW and the second output node OUT2, with the anode of the diode coupled to OUT2 and the cathode coupled to SW. The capacitor C and load resistor R_(L) are coupled between first output node OUT1 and second output node OUT2. In one embodiment, OUT2 node is a reference ground voltage for the buck converter. In an example embodiment, the buck converter can receive an AC input voltage (i.e., off-line converter) instead of a DC input voltage. In that scenario, the AC input voltage is first converted into a DC input voltage using known techniques before converting it to a DC output voltage. It is understood that all embodiments described in this disclosure are applicable to both DC-DC converters as well as AC-DC (i.e., off-line) converters.

FIG. 2 is a timing diagram illustrating an operation of the buck converter of FIG. 1, according to an example embodiment. In FIG. 2, x-axis represents time and y-axis represents either voltage or current of various signals. Time axis includes various points in time, t0 through t3, represented by vertical dotted lines (line representing t0 overlaps with y-axis). FIG. 2 shows CTRL signal for switching the switch S, voltage V_(L) across the inductor L, voltage V_(D) across the diode D, output voltage V_(OUT1) across the load resistor R_(L), and current I_(L) through the inductor L. The time period between points t0 and t3 constitutes one switching period for the switch SW. The second output node OUT2 is a reference ground voltage node of the buck converter. FIG. 2 describes an operation of the buck converter when the components of the converter are ideal. It is understood that the principle of operation is equally applicable to non-ideal converters.

An operation of the buck converter 100 is described below along with the timing diagram of FIG. 2. Before point t0, the switch S is open (i.e., in the OFF state) and there is no current flowing in the converter. At point t0, the switch S is closed (i.e., in the ON state) and current I_(L) flows through the inductor L until the switch S is open again at point t1 as shown in FIG. 2. When switch S is closed, a voltage V_(L) across the inductor L is given by a difference of voltage values at switching node SW (i.e., V_(SW)) and at first output node OUT1 (i.e., V_(OUT1)). The voltage V_(L) across the inductor produces a current flow through the inductor that increases from point t0 to point t1. A value of V_(L) during the ON state of switch SW (i.e., between points t0 and t1) is equal to a difference between input voltage V_(INP) and output voltage V_(OUT1). The voltage V_(D) across the diode D is the same as the voltage at the switching node SW. During the ON state, V_(D) is equal to V_(INP).

At point t1, the switch S is opened and the input voltage source is disconnected in the converter. During this OFF state, the voltage V_(L) across the inductor decreases and becomes negative as the switching node voltage V_(SW) is zero and the output voltage is still at V_(OUT1). Accordingly, the current I_(L) flowing through the inductor decreases and the diode is forward biased such that the voltage V_(D) across the diode is zero (for an ideal diode). The current I_(L) decreases in value until the switch is closed again at point t2. In an example embodiment implementing a continuous mode of operation depicted in FIG. 2, the inductor current I_(L) does not reach zero. Alternatively in an embodiment implementing a discontinuous mode of operation, the inductor current I_(L) does reach zero during the OFF state in each switching cycle. This disclosure is applicable to both a continuous mode and a discontinuous mode operation of buck converters (and buck-boost converters).

The time period between points t0 and t2 constitutes one switching cycle for the switch S while converting an input voltage V_(INP) to an output voltage V_(OUT1). Next at point t2, the switch is closed again until point t3, when it is opened again. It is understood that the switch can be turned ON and OFF for a plurality of switching cycles to convert an input DC voltage to an output DC voltage. A ratio of the period of time the switch is ON compared to a time period of one switching cycle is defined as a duty cycle of the converter operating in a continuous mode of operation. For example, the duty cycle of the buck converter 100 is given by (t1−t0)/(t2−t0). It is important to be able to control the period of time the switch is ON (i.e., duty cycle of the converter in a continuous mode of operation) and FIGS. 3 through 5 describe various feedback techniques that describe the same.

FIG. 3 is a circuit diagram illustrating a feedback scheme for non-isolated power supplies using current reference, according to an example embodiment. The buck converter 300 shown in FIG. 3 is the same converter 100 described above with reference to FIGS. 1 and 2. Additionally, FIG. 3 shows a controller 310 that controls the ON time of the switch S using a feedback scheme that is described below. The controller 310 includes an operational amplifier (OPAMP) 320 configured to operate as an integrator, a pulse-width modulator (PWM) circuit 330, and circuitry to generate a reference signal. In an example embodiment depicted in FIG. 3, the reference signal is generated using a current reference I_(REF).

The feedback scheme relies on an observation that an average voltage V_(D) across the diode D is the same as the output voltage across the load resistor R_(L) over one or more switching cycles of the switch S. Accordingly, the feedback scheme uses this observation and controls the switch S by generating a feedback signal based on the voltage V_(D) across the diode D instead of the output voltage directly. An example advantage with this feedback scheme is an ability to be able sense the voltage across the diode D continuously instead of being able to sense only once per switching cycle for schemes that are based on the output voltage. Another example advantage is that the proposed feedback scheme is not limited to sensing the output voltage only after switching of the switch S.

The feedback scheme of the converter 300 is described below. The feedback scheme uses a current balance method to create a feedback signal that controls the turning ON and OFF of the switch S. OPAMP 320 is configured to operate as an integrator such that the OPAMP will integrate any difference of voltages across its inverting and non-inverting inputs. The non-inverting input of the OPAMP 320 is coupled to the switching node SW of the converter 300 such that a voltage level at the non-inverting input is the same as a voltage level across the diode D. The inverting input INV of the OPAMP 320 is coupled to the switching node SW through a current reference I_(REF) and to the second output node OUT2 through feedback resistor R_(FB). Capacitor C_(INT) is coupled between the inverting input and an output INT of the OPAMP 320. In an example embodiment, the current reference I_(REF) is generated within the controller 310. Alternatively, I_(REF) is generated external to the converter 300. The resistor R_(FB) can be either integrated within the controller 310 or alternatively can be implemented external to the converter 300.

The OPAMP 320 operates as an integrator in a closed loop configuration, which will ensure that the inverting input of the OPAMP 320 is at a same voltage as the non-inverting input. Accordingly, a voltage across the feedback resistor R_(FB) is going to be the same as that of across the diode D due to the closed loop configuration of the OPAMP 320. Because any current flowing through the non-inverting input of the OPAMP 320 is negligible, the entire current from the current reference I_(REF) flows through the feedback resistor R_(FB). Therefore, the values of I_(REF) and R_(FB) can be chosen such that a product of I_(REF) and R_(FB) would be same as an average voltage difference between voltage values of the switching node SW and the second output node OUT2. In a buck converter, the average voltage difference between voltage values of the switching node SW and the second output node OUT2 is the voltage V_(D) across diode D. An average voltage difference between voltage values of the switching node SW and the second output node OUT2 is same as the output voltage, as detailed above. The integrator would integrate any voltage difference between the OPAMP's inverting and non-inverting inputs using the integrating capacitor C_(INT), and generates an output V_(INT). In other words, the integrator integrates a difference between a voltage value of the reference signal (i.e., I_(REF)*R_(FB)), and a voltage difference between voltage values of the switching node SW and the second output node OUT2. When the feedback loop reaches a steady-state mode of operation, the switch S is controlled such that the output voltage across the load (and diode voltage V_(D)) is the same as the voltage of the reference signal.

The output signal of the integrator V_(INT) is then processed by the PWM circuit 330 to generate a control signal CTRL that controls the switching of the switch S by controlling the ON time of the switch S. The controller 310 controls the switch such that an average voltage value of the output voltage (or an average voltage across diode D) over one or more plurality of switching cycles is the same as the voltage value of the reference signal.

The feedback loop's operation for an example buck converter can be described as below. In an example scenario when the output voltage is larger than its designed value at the steady-state operation, the average diode voltage V_(D) will also be larger than the voltage value of the reference signal (i.e., I_(REF)*R_(FB)). In such example scenario, the integrated output voltage V_(INT) reduces from its steady-state value. A reduced V_(INT) will result in a reduced ON time for the CTRL signal controlling switch S, which in turn will reduce the output voltage and its corresponding diode voltage V_(D). The feedback loop will keep reducing the output voltage (and diode voltage V_(D)) in each of the switching cycles until the output voltage reaches its steady-state value where an average value of the diode voltage V_(D) is the same as the voltage value of the reference signal.

Alternatively, when the output voltage is smaller than its designed value at the steady-state operation, the diode voltage V_(D) will also be smaller than the voltage value of the reference signal (i.e., I_(REF)*R_(FB)). In such example scenario, the integrated output voltage V_(INT) increases from its steady-state value. An increased V_(INT) will result in an increased ON time for the CTRL signal controlling switch S, which in turn will increase the output voltage and diode voltage V_(D). The feedback loop will keep increasing the output voltage (and diode voltage V_(D)) in each of the switching cycles until the output voltage reaches its steady-state value where an average value of the diode voltage V_(D) is the same as the voltage value of the reference signal.

One example advantage with the proposed feedback scheme described in FIG. 3 is an ability to be able to sense the voltage across the diode D continuously instead of being able to sense only once per switching cycle for schemes that are based on the output voltage. Conventional feedback schemes (e.g., FIG. 6) that sense output voltage directly are limited to sensing only when current is flowing though the inductor (i.e., I_(L) is not zero). Accordingly, in a discontinuous mode of operation when the inductor current I_(L) is zero, the control signal CTRL for the switch S cannot be generated and hence the converter cannot be controlled. This is especially a problem for the discontinuous mode of operation where the inductor current is zero for a significant portion of the switching cycle. Because the proposed scheme uses the switching node as the negative supply voltage of the controller, the control signal can be generated even while the inductor current I_(L) is zero.

Another example advantage with the proposed feedback scheme described in FIG. 3 is an elimination of any high voltage components in the feedback path. In an example embodiment when the buck converter 300 is operating on high voltages of up to 110V input, conventional feedback schemes used in non-isolated converters sense the output voltage across the load and require expensive high voltage components such as a high voltage diode or a high voltage bipolar junction transistor (BJT) in the feedback path to handle voltages as high as (or even higher to account for switching overshoots) 110V. The proposed feedback scheme operates on voltage V_(D) across the diode D and uses the switching node SW as a negative supply voltage for the controller 310. By using the switching node SW as the negative supply voltage of the controller, none of the components of the controller 310 including OPAMP 320 and PWM circuit 330 need to handle a high voltage. Accordingly, the proposed feedback scheme eliminates the usage of high voltage components in the feedback path by operating on the diode voltage V_(D) instead of the output voltage. Other example embodiments for implementing the proposed feedback scheme are described below with reference to FIGS. 4 and 5.

In an example embodiment, the proposed feedback scheme described above with reference to a buck converter of FIG. 3 is also applicable to a buck-boost type converter.

FIG. 4 is a circuit diagram illustrating a feedback scheme for non-isolated power supplies using a voltage reference, according to an example embodiment. The buck converter 400 shown in FIG. 4 is the same converter 300 described above with reference to FIG. 3 except that the controller 410 uses a voltage source V_(REF) to generate the reference signal. In some example embodiments, integrating a precision current source in to an integrated circuit is relatively difficult. One way to avoid implementing a current source reference is to implement a voltage source and a reference resistor as shown in FIG. 4. The below description of FIG. 4 refers to only the differences between FIGS. 3 and 4, namely the generation of reference signals by using a current source I_(REF) in FIG. 3, and a voltage source V_(REF) and reference resistor R_(REF) in FIG. 4. It is understood that all other aspects described above with reference to FIG. 3 are equally applicable to converter of FIG. 4.

Controller 410 includes OPAMP 320, PWM circuit 330, and voltage reference V_(REF) and resistor R_(REF) for generating a reference signal. The non-inverting input of the OPAMP 320 is coupled to the switching node SW of the converter 400 such that a voltage level at the non-inverting input is the same as a voltage level across the diode D. The inverting input INV of the OPAMP 320 is coupled to the switching node SW through a reference resistor R_(REF) and a voltage reference V_(REF), and to the second output node OUT2 through feedback resistor R_(FB). In an example embodiment, the current reference V_(REF) is generated within the controller 410. Alternatively, V_(REF) is generated external to the converter 400. The resistors R_(FB) and R_(REF) can be either integrated within the controller 410 or alternatively can be implemented external to the converter 400.

Controller 410 implements the proposed feedback scheme by first generating a reference signal that is based on the voltage source V_(REF), the reference resistor R_(REF), and the feedback resistor R_(FB). A voltage value of the reference signal is a voltage value across the feedback resistor R_(FB) that is given by a product of a voltage value of V_(REF) and a ratio of resistor values of R_(FB) and R_(REF) (i.e., V_(REF)*R_(FB)/R_(REF)). Once the reference signal is generated, the rest of the proposed feedback scheme is implemented similar to the scheme described above with reference to FIG. 3, by integrating a difference between the voltage value of the generated reference signal, and a voltage difference between voltage values of the switching node SW and the second output node OUT2 (i.e., a voltage V_(D) across the diode D). Next, the integrated voltage difference is processed in the PWM circuit to generate a control signal CTRL that controls the switching states of switch S.

One example advantage of the proposed scheme of FIG. 4 using a voltage reference is an ability to vary a time constant of the integrator without affecting the output voltage of the converter. The time constant of the integrator depends on the value of the integrator capacitance C_(INT) and the resistance values of R_(REF) and R_(FB). The voltage reference V_(REF), and resistors R_(FB) and R_(REF) are chosen such that output voltage (and an average diode voltage V_(D)) is same as a product of a voltage value of V_(REF) and a ratio of resistor values of R_(FB) and R_(REF) (i.e., V_(REF)*R_(FB)/R_(REF)). That is, while the individual values of R_(REF) and R_(FB) control the time constant of the integrator, the output voltage is controlled by only a ratio of the resistor values. Accordingly, the time constant of the integrator can be varied without affecting an average voltage value of the output voltage, wherein the time constant is varied by changing the resistance value of the feedback resistor and reference resistor, while keeping a ratio of resistance values of the feedback resistor and the reference resistor constant.

FIG. 5 is a circuit diagram illustrating a feedback scheme for non-isolated power supplies using current mirrors, according to an example embodiment. The buck converter 500 shown in FIG. 5 is the same converter 400 described above with reference to FIG. 4 except that the controller 510 implements an integrator by adding offset and current mirrors. In some example embodiments, it is not recommended to have the non-inverting input of the OPAMP to be referenced to the negative supply voltage of the controller. In such embodiments, the integrator can be modified to add offset and current mirrors as shown in FIG. 5. The below description of FIG. 5 refers to only the differences between FIGS. 4 and 5, namely the implementation of the integrator using current mirrors in FIG. 5. It is understood that all other aspects described above with reference to FIG. 4 are equally applicable to converter of FIG. 5.

The integrator of controller 510 is implemented by OPAMP1 520 and OPAMP2 530 and current mirrors using metal-oxide semiconductor (MOS) transistors T3 through T8. The non-inverting inputs of OPAMPS 520 and 530 are referenced to V_(REF) instead of the negative supply voltage of the converter (i.e., switching node of the converter). This implementation of the integrator is an advantageous option in embodiments where the capacitor of the integrator is integrated on-chip. Current mirrors can be scaled by selecting the size of the MOSFETs T3/T4 and T7/T8. One example advantage with the controller 510 over the controller 310 is that a value of the integrator capacitance C_(INT) needed in the controller 510 is much smaller than that of FIG. 3. For example, C_(INT) for controller 310 is about 1 nF and C_(INT) for controller 510 is about 20 pF. It is understood that the feedback scheme to control the switch S of the converter 500 is the same as that of converter 400 except in an implementation of the integrator.

The foregoing description of the embodiments of the disclosure has been presented for the purpose of illustration; it is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Persons skilled in the relevant art can appreciate that many modifications and variations are possible in light of the above disclosure.

Some portions of this description describe the embodiments of the invention in terms of symbolic representations of operations on information. These representations are commonly used by those skilled in the data processing arts to convey the substance of their work effectively to others skilled in the art. These operations, while described functionally, computationally, or logically, are understood to be implemented by computer programs or equivalent electrical circuits, microcode, or the like. Furthermore, it has also proven convenient at times, to refer to these arrangements of operations as modules, without loss of generality. The described operations and their associated modules may be embodied in software, firmware, hardware, or any combinations thereof.

Any of the operations described herein may be performed or implemented with one or more hardware or software modules, alone or in combination with other devices. In one embodiment, a software module is implemented with a computer program product comprising a computer-readable medium containing computer program code, which can be executed by a computer processor for performing any or all of the steps, operations, or processes described.

Embodiments of the invention may also relate to an apparatus for performing the operations herein. This apparatus may be specially constructed for the required purposes, and/or it may comprise a general-purpose computing device selectively activated or reconfigured by a computer program stored in the computer. Such a computer program may be stored in a tangible computer readable storage medium or any type of media suitable for storing electronic instructions, and coupled to a computer system bus. Furthermore, any computing systems referred to in the specification may include a single processor or may be architectures employing multiple processor designs for increased computing capability.

Embodiments of the invention may also relate to a computer data signal embodied in a carrier wave, where the computer data signal includes any embodiment of a computer program product or other data combination described herein. The computer data signal is a product that is presented in a tangible medium or carrier wave and modulated or otherwise encoded in the carrier wave, which is tangible, and transmitted according to any suitable transmission method.

Finally, the language used in the specification has been principally selected for readability and instructional purposes, and it may not have been selected to delineate or circumscribe the inventive subject matter. It is therefore intended that the scope of the invention be limited not by this detailed description, but rather by any claims that issue on an application based hereon. Accordingly, the disclosure of the embodiments of the invention is intended to be illustrative, but not limiting, of the scope of the invention, which is set forth in the following claims. 

What is claimed is:
 1. A switching power converter comprising: a switch coupled between an input terminal for receiving an input voltage and a switching node; an inductor coupled between the switching node and a first output terminal; a diode coupled between the switching node and a second output terminal, the first and second output terminals configured to provide an output voltage to a load; and a controller coupled to the switching node, the controller configured to generate a control signal for turning on and turning off the switch at each switching cycle of a plurality of switching cycles of the switch, wherein the controller generates the control signal by: generating a reference signal, integrating a difference between a voltage value of the generated reference signal, and a voltage difference between voltage values of the switching node and the second output terminal, and generating the control signal by processing the integrated voltage difference.
 2. The switching power converter of claim 1, wherein an average voltage value of the output voltage over one or more of the plurality of switching cycles is the same as the voltage value of the reference signal.
 3. The switching power converter of claim 1, wherein the controller comprises an operational amplifier implemented as an integrator, the operational amplifier integrating a voltage difference between voltages on its inverting input and non-inverting input.
 4. The switching power converter of claim 3, wherein the controller further comprises a feedback resistor coupled between the inverting input of the operational amplifier and the second output terminal.
 5. The switching power converter of claim 4, wherein the controller further comprises a current reference coupled between the inverting input of the operational amplifier and the switching node.
 6. The switching power converter of claim 5, wherein an average voltage difference between voltage values of the switching node and the second output terminal is same as a product of a resistance value of the feedback resistor and a current value of the current source.
 7. The switching power converter of claim 4, wherein the controller further comprises a reference resistor and a voltage reference, the reference resistor coupled between the inverting input of the operational amplifier and the voltage reference, and the voltage reference coupled between the reference resistor and the switching node.
 8. The switching power converter of claim 7, wherein an average voltage difference between voltage values of the switching node and the second output terminal is same as a product of a ratio of resistance values of the feedback resistor and the reference resistors, and a voltage value of the voltage source.
 9. The switching power converter of claim 7, wherein the controller is further configured to vary a time constant of the integrator without affecting an average voltage value of the output voltage, the time constant varied by changing the resistance value of the feedback resistor and the reference resistor, while keeping a ratio of resistance values of the feedback resistor and the reference resistor constant.
 10. The switching power converter of claim 3, wherein the non-inverting input of the operational amplifier is coupled to the switching node for providing a voltage level associated with the switching node as a reference ground voltage of the operational amplifier.
 11. In a controller, a method of controlling a switching power converter, the switching power converter including a switch coupled between an input terminal for receiving an input voltage and an switching node, an inductor coupled between the switching node and a first output terminal, and a diode coupled between the switching node and a second output terminal, the first and second output terminals configured to provide an output voltage to a load, the method comprising: generating a reference signal; integrating a difference between a voltage value of the generated reference signal, and a voltage difference between voltage values of the switching node and the second output terminal; and generating a control signal by processing the integrated voltage difference, the control signal turns on and turns off the switch at each switching cycle of a plurality of switching cycles.
 12. The method of claim 11, wherein the reference signal is generated such that an average voltage value of the output voltage over one or more of the plurality of switching cycles is the same as the voltage value of the reference signal.
 13. The method of claim 11, wherein the difference between the voltage value of the generated reference signal, and the voltage difference between voltage values of the switching node and the second output terminal is integrated using an operational amplifier implemented as an integrator, the operational amplifier integrating a voltage difference between voltages on its inverting input and non-inverting input.
 14. The method of claim 13, wherein the reference signal is generated using a feedback resistor coupled between the inverting input of the operational amplifier and the second output terminal.
 15. The method of claim 14, wherein the reference signal is generated using a current reference coupled between the inverting input of the operational amplifier and the switching node.
 16. The method of claim 15, wherein the generated reference signal has a voltage value equal to a product of a resistance value of the feedback resistor and a current value of the current source.
 17. The method of claim 16, wherein the voltage value of the generated reference signal is the same as an average voltage value of the voltage difference between voltage values of the switching node and the second output terminal.
 18. The method of claim 14, wherein the reference signal is generated using a reference resistor and a voltage reference, the reference resistor coupled between the inverting input of the operational amplifier and the voltage reference, and the voltage reference coupled between the reference resistor and the switching node.
 19. The method of claim 18, wherein the generated reference signal has a voltage value equal to a product of a ratio of resistance values of the feedback resistor and the reference resistors, and a voltage value of the voltage source.
 20. The method of claim 19, wherein the voltage value of the generated reference signal is the same as an average voltage value of the voltage difference between voltage values of the switching node and the second output terminal. 